A semiconductor-on-insulator structure includes a substrate and a buried insulator stack overlying the substrate. The buried insulator stack includes a first dielectric layer and a recess-resistant layer overlying the first dielectric layer. A second dielectric layer can overlie the recess-resistant layer. A semiconductor layer overlying the buried insulator stack. Active devices, such as transistors and diodes, can be formed in the semiconductor layer.
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1. A method of fabricating a semiconductor-on-insulator chip, comprising the steps of:
providing a donor wafer substrate;
implanting ions into said donor wafer substrate to form an implanted layer and a semiconductor film overlaying said implanted layer;
forming a recess-resistant layer of silicon nitride having an etch rate of less than 10 angstroms per minute in a wet cleaning solution, said recess-resistant layer overlying the semiconductor film, the recess-resistant layer forming the topmost layer of the a donor wafer;
providing a target wafer comprising of a recess-resistant layer of silicon nitride having an etch rate of less than 10 angstroms per minute in a wet cleaning solution, said recess-resistant layer overlying a first dielectric layer, the first dielectric layer overlying a substrate, the target wafer having a top surface;
beta bonding the top most recess-resistant layer of the donor wafer to the recess-resistant top surface of the target wafer;
cleaving the semiconductor film from the donor wafer, the semiconductor film adhering to the target wafer so as to provide a substrate device comprising a the semiconductor film overlying a buried insulator stack, the buried insulator stack comprising the recess-resistant layer overlying the first dielectric layer;
annealing the target wafer to strengthen the bond between semiconductor film and the target wafer after the semiconductor film adheres to the target wafer, and after the cleaving step forms the semiconductor film;
patterning a portion of the semiconductor film to form semiconductor mesas; and forming active devices on the semiconductor mesas.
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The present invention is related to commonly-assigned U.S. patent application Ser. No. 10/379,873, entitled “Method of Forming Strained Silicon on Insulator Substrate,” filed Mar. 5, 2003, which application is incorporated herein by reference as if repeated in its entirety.
The present invention relates generally to semiconductor materials, and more particularly to semiconductor-on-insulator substrates with a recess-resistant layer.
Traditional silicon-on-insulator (SOI) integrated circuits are formed on SOI substrates. A cross-section of a silicon-on-insulator (SOI) substrate 100 is illustrated in
In an SOI chip, as shown in
Active devices formed on SOI substrates offer many advantages over their bulk counterparts, including absence of reverse body effect, absence of latch-up, soft-error immunity, and elimination of junction capacitance typically encountered in bulk silicon devices. SOI technology therefore enables higher speed performance, higher packing density, and reduced power consumption. At present, commercial products using SOI technology employ an uniform active layer thickness and shallow trench isolation.
One type of SOI transistor employs a very thin silicon active layer 110. In some cases, the silicon active layer 10 thickness can be as thin as a third of the gate length. For example, if the gate length is 30 nm, the silicon active layer 110 may have a thickness of 10 nm or thinner. This type of SOI transistor is known as an ultra-thin body (UTB) transistor or a depleted-substrate transistor (DST).
When the thickness of the silicon active layer 110 is as thin as 10 nm, mesa isolation could be a more appropriate isolation scheme for the transistors as compared to shallow trench isolation. In mesa isolation, trenches 122 are formed in the active layer 110, as shown in
One problem of the mesa isolation is that the exposed buried oxide layer 112 surface will be recessed in subsequent chemical treatments such as wafer cleaning steps. This recess is illustrated in
The present invention describes embodiments of an improved method of fabricating strained-silicon-on-insulator substrates. In one embodiment, a recess-resistant film is used with the buried insulator to prevent erosion of the buried insulator during subsequent processing steps. For example, the recess-resistant film can be a silicon nitride film, which etches ten times more slowly than silicon oxide for common wet etch processes.
In one aspect, the present invention provides a semiconductor-on-insulator substrate with a recess-resistant buried insulator. The buried insulator has a recess-resistant layer that has negligible etch rates in commonly used wet cleaning solutions.
The present invention provides several methods of fabricating the substrate structures disclosed herein. In certain of these methods, a thin film stack is transferred from a donor wafer to a target wafer. One method employs the bonding of a donor wafer with an implanted layer to a target wafer to form a wafer assembly. The thin film stack can be separated at an implanted layer to produce the desired substrate.
In another embodiment, a donor wafer is bonded to a target wafer. The donor wafer includes an interface between a strained layer and a relaxed layer. The two wafers can be separated at the interface to produce the desire substrate.
Aspects of the present invention provide advantages over prior art devices. For example, the buried insulating layer will not include recesses. This feature helps to minimize parasitic capacitance between the substrate and metal lines running over the device. This feature minimizes any concentration of electric field lines around the exposed corners of the silicon mesas and therefore enhance device reliability.
For a more complete following descriptions taken in conjunction with the accompanying drawings, in which understanding of the present invention, and the advantages thereof, reference is now made to the:
The making and using of the presently preferred embodiments are discussed in detail below. It should be appreciated, however, that the present invention provides many applicable inventive concepts that can be embodied in a wide variety of specific contexts. The specific embodiments discussed are merely illustrative of specific ways to make and use the invention, and do not limit the scope of the invention.
Aspects of the present invention relate generally to semiconductor materials, and more particularly to semiconductor-on-insulator substrates with a recess-resistant layer. Aspects of the present invention are also related to the manufacture of metal oxide semiconductor field effect transistors on semiconductor-on-insulator substrates with a recess-resistant layer.
According to the preferred embodiment of the present invention, a recess-resistant layer is provided in the buried insulator stack of a semiconductor-on-insulator wafer for the purpose of restricting the amount of recess in the exposed insulator stack during wafer processing such as wet cleaning of wafers in dilute hydrofluoric acid. This feature can be useful where the mesa isolation scheme is adopted in the fabrication of an semiconductor-on-insulator integrated circuit chip. Semiconductor-on-insulator integrated circuit chips employing the mesa isolation scheme have exposed buried insulator surfaces. The exposed buried insulator surfaces are susceptible to chemical attack or etching during wafer processing. In certain aspects, this invention teaches a substrate structure where a recess-resistant layer is provided.
Referring now to
The semiconductor mesas 216 are isolated from the substrate 214 by a buried insulator stack 212, as schematically shown in FIG. 3. The substrate 214 is preferably a silicon substrate, which is typically undoped but may be lightly doped. Other materials such as germanium, quartz, sapphire, and glass could alternatively be used as the substrate 214 material.
According to the preferred embodiment of the present invention, the buried insulator stack 212 comprises at least a layer of recess-resistant layer 224, which is resistant to commonly used wafer wet cleaning solutions. That is, the etch rate of the recess-resistant layer is extremely slow in commonly used wafer wet cleaning solutions so that the total amount etched is negligible. The thickness of the recess-resistant layer may range from about 2 angstroms to about 1000 angstroms, and is more preferably from about 10 angstroms to about 200 angstroms.
The recess-resistant layer 224 overlies a first dielectric layer 226. The first dielectric layer 226 can be a dielectric material such as silicon oxide, for example, and may have a thickness ranging from about 100 angstroms to about 5000 angstroms. Other dielectric layers such as silicon nitride, silicon oxynitride, aluminum oxide, or silicon carbide, as examples, can be used as the first dielectric layer 226.
To form isolation trenches 222, one commonly used wet cleaning solution is dilute hydrofluoric acid. Dilute hydrofluoric acid may, for example, be formed by a mixture of 1 part of concentrated (49%) hydrofluoric (HF) acid and 25 parts of water H2O. This mixture is also commonly known as 25:1 HF. Another commonly used wafer cleaning solution is a mixture of concentrated sulphuric acid and hydrogen peroxide, commonly known as piranha solution.
The recess-resistant layer 224 of the buried insulator stack 212 preferably comprises a dielectric material that has very slow or negligible etch rates in commonly used wet cleaning solutions such as the above-mentioned chemicals or solutions. As shown in
In the preferred embodiment, the recess-resistant layer 224 is comprised of silicon nitride (e.g., Si3N4). The etch rate of stoichiometric silicon nitride Si3N4 in 25:1 HF is about 1 to 6 angstroms per minute. The etch rate of thermally grown silicon oxide in 25:1 HF is more than ten times higher, e.g., about 100 angstroms per minute. By using silicon nitride as a recess-resistant layer on the top surface of the buried insulator stack, as illustrated in
Other recess-resistant materials can be used to form layer 224. For example, the layer 224 could be a nitrogen containing layer other than Si3N4. For example, the recess-resistant layer 224 could comprise of silicon nitride SixNy, silicon oxynitride SiOxNy, silicon oxime SiOxNy:Hz, or any combinations thereof.
In another embodiment of the present invention, the recess-resistant layer 224 is not the topmost layer of the buried insulator stack 212. For example,
The recess-resistant layer 224 overlies the bottom-most dielectric layer 226. The recess-resistant layer 224 in this embodiment is preferably silicon nitride. The recess-resistant layer is preferably about 2 to about 1000 angstroms thick and more preferably from about 10 to about 200 angstroms thick. In the preferred embodiment, the recess-resistant layer 224 has an etch rate that is at least about ten times less than the etch rate of the second dielectric layer 228.
The second dielectric layer 228 overlies the recess-resistant layer 224. In this embodiment, the second dielectric layer 228 is in contact with the semiconductor mesas 216 and is preferably silicon oxide. The second dielectric layer 228 serves the purpose of providing a high quality interface between the buried insulator stack 212 and the semiconductor mesas 216. It is known that the interface between silicon oxide and silicon has a much better and lower interface state density than the interface between silicon nitride and silicon.
A second dielectric layer 228 with good interface properties and low bulk trap density can be helpful to achieve good electrical characteristics in the active devices (not shown in FIG. 4). This interface can be especially important in active devices with ultra-thin body thicknesses, in which case the mobile carriers flowing between the source and drain are in close proximity to the interface between the active layer 210 and the buried insulator stack 212. For example, trapped charges or charge centers near the top of the buried insulator stack 212 may degrade the carrier mobility in the channel region of an ultra-thin body transistor by Coulombic scattering. The use of a high quality second dielectric layer 228 with a low bulk trap density and a low interface trap density ensures that mobility degradation due to Coulombic scattering is kept to a minimum.
In addition, since the second dielectric layer 228 might not have a very slow etch rate in common wet cleaning solutions and may be removed by the cleaning solutions, the thickness of the second dielectric layer 228 is preferably kept very thin to limit the amount of recess in the buried insulator stack. If the second dielectric layer is silicon oxide, the recess of the buried insulator stack in the exposed portion will be approximately equal to the thickness of the second dielectric layer 228. According to the preferred embodiment, the second dielectric layer 228 may have a thickness in the range of about 10 to about 200 angstroms.
An example of how a substrate of
The target wafer of
Referring now to
The peak of the implanted ions is at a depth xd below the interface between substrate 230 and second dielectric layer 228. The implanted ions result in an implanted layer 234 and a silicon film 224, as shown in
The next process step is the bonding of the top surface of the donor wafer 205, i.e., the surface of the second dielectric 228, to the top surface of the handle wafer 200, i.e., the surface of the recess-resistant layer 224. This bonding process is illustrated in
Beta bonding produces a joint 236 between the donor wafer 205 and the target wafer 200. The target wafer 200 will act as a mechanical support for the thin film stack comprising of the silicon film 210 and the second dielectric layer 228 when the thin film stack is separated from the donor wafer 205. Prior to beta bonding, the surfaces of the wafers to be bonded are preferably cleaned to remove any residual liquids or particles from the wafer surfaces.
The bonding process forms a wafer assembly, as shown in
One of the separated wafers is a reusable silicon substrate. The other separated wafer is a hybrid SOI substrate 200 with a silicon nitride recess-resistant layer 224, as shown in
Following the wafer separation process, final bonding between the thin film stack 224/210 and the target wafer 200 is performed to yield the desired recess-resistant SOI substrate. This bonding usually requires a high temperature anneal, where the annealing temperature is typically above about 700 degrees Celsius. The final bonding step creates a strong bond between the thin film stack 224/210 and the target wafer 200. It is believed that covalent bonds are form at the joint 236 when the wafer is anneal at a sufficiently high temperature for a sufficient period of time. During the annealing, a layer of thermal oxide 238 may be grown on the silicon thin film 210 surface, as shown in
Several other combinations of donor and target wafers in the wafer bonding and wafer separation technique as described previously will result in the formation of the same substrate of
In
It is understood, according to this invention, that the substrate of
The preceding description relates to methods of manufacturing semiconductor-on-insulator substrates with a recess-resistant layer using a donor wafer with an implanted layer. In those cases, the wafer separation is initiated by a heat treatment. According to another method embodiment of this invention, the donor wafer may depend on other mechanisms to initiate the cleavage process for wafer separation. For example, the wafer separation process may be an atomic layer cleaving process or nanocleave process, such as the one described by Michael I. Current et al., in a paper entitled “Atomic layer cleaving with SiGe strain layers for fabrication of Si and Ge-rich SOI device layers,” published in pp. 11-12 of the proceedings of the 2001 IEEE International SOI Conference (October 2001) and incorporated herein by reference. The nanocleave transfer process results in a layer separation using a strain-layer cleave plane.
A donor wafer 205, as shown in
The thickness of the strained silicon layer 210′ is preferably less than about 500 angstroms and the strain may vary from about 0.01% to about 4%. The germanium atomic concentration in the relaxed SiGe layer 240 may range from about 0% to about 100%. There is an interface between the strained silicon layer 210′ and the relaxed SiGe layer 240 and a large strain gradient exists across this interface. The strained silicon layer 210′ and relaxed SiGe layer 240 may be epitaxially grown using chemical vapor deposition.
In another embodiment, the donor substrate 230′ may comprise a material that has a lattice constant that is different than that of silicon. For example, if the strained silicon layer 210′ is to be comprised of a tensile strain, the bulk substrate 230′ of the donor wafer 205 should have a lattice constant larger than that of silicon, e.g., a bulk silicon-germanium (SiGe) wafer. If the strained silicon layer 210′ is to be comprised of a compressive strain, the bulk substrate should have a lattice constant smaller than that of silicon, e.g., a bulk silicon-germanium-carbon (SiGeC) wafer. In order for the lattice constant of SiGeC to be smaller than that of silicon, the composition of germanium x and the composition of carbon y in the bulk Si1-x-yGexCy can be such that y>0.1x. Details of using a bulk substrate are provided in co-pending application Ser. No.10/379,873, which application is incorporated herein by reference.
Returning to the process flow of
A cut or cleave can be made at or near the interface between the strained silicon layer 210′ and the relaxed SiGe layer 240 using a process similar to the nanocleave process. The cleave plane will be initiated near the interface between the strained Si layer 210′ and the relaxed-SiGe layer 240. Following the wafer separation process, final bonding between the strained silicon layer 210′ and the target wafer 200 is performed to yield the desired recess-resistant SOI substrate. This final bonding typically requires a high temperature anneal, where the annealing temperature is typically above about 700 degrees Celsius. This results in the formation of a strained-Si layer 210′ on an insulator structure 212 as illustrated in
A process of forming a device of the present invention has been described to include a wafer bonding and separation process. As examples, the wafer bonding and separation process can be a Smartcut™ process, or a Nanocleave™ process, both available from Silicon Genesis Corporation. Details of bonding and separation processes are also provided in U.S. Pat. Nos. 5,013,681, 5,374,564, 5,863,830, 6,355,541, 6,368,938, and 6,486,008, each of which is incorporated herein by reference.
It will be appreciated that the strained-silicon-on-insulator substrate with a recess-resistant layer may be manufactured by the above wafer bonding and wafer separation method using other combinations of donor and target wafers. For example, the donor wafer may have a silicon oxide overlying the strained silicon layer, or a silicon nitride on a silicon oxide stack overlying the strained silicon layer, and the target wafer may have a silicon oxide layer overlying the recess-resistant layer.
The processes described above utilize wafer bonding and separation techniques. It is understood, however, that the present invention could also be achieved using deposition processes. For example, the recess-resistant layer 224 (see e.g.,
The preceding description of the present invention relates to the formation of substrates with recess-resistant layers. The present invention not only teaches the formation of such substrates, but also devices fabricated on such substrates. A method of forming a semiconductor-on-insulator chip with mesa isolation and a recess-resistant layer is to be described next.
Referring now to
Following active region definition using a mask, the active layer 210 is etched using techniques known and used in the art. If the active layer 210 is comprised of silicon, a dry plasma etch using fluorine chemistry may be used. The mask 242 is then removed to yield the semiconductor mesas 216, the cross-sections of which are shown in
The formation of the semiconductor mesas 216 exposes regions of the buried insulator 212 not covered by the semiconductor mesas. In the subsequent process steps, the wafer may be subjected to wet cleaning, for example, before the wafer enters a gate dielectric deposition or growth chamber. The wet cleaning solutions potentially etch into the buried insulator and result in a recessed buried insulator if it is not protected by the recess-resistant layer 224. The recess-resistant layer 224, as shown in
A typical active device or a transistor is formed as follows. The resulting structure is shown in
The gate electrode 246 material is then deposited. The gate material may be polycrystalline-silicon (poly-Si), poly-crystalline silicon-germanium (poly-SiGe), a refractory metal such as molybdenum and tungsten, compounds such as titanium nitride, or other conducting materials. A gate mask (not shown) is defined and the underlying gate material is etched to form the gate electrode. The gate etch stops on the gate dielectric 244, and the gate is electrically isolated from the transistor structure by the gate dielectric 244. In the preferred embodiment, the gate 246 material is poly-Si and the gate dielectric 244 is silicon oxynitride. A plasma etch using chlorine and bromine chemistry may be used for the gate electrode etching.
After gate 246 definition, the gate mask can be removed. The source and drain extensions 248 are formed next. This may be achieved by ion implantation, plasma immersion ion implantation (PIII), or other techniques known and used in the art.
Next, a spacer 250 is formed on the sidewalls of the gate 246 by deposition and selective etching of the spacer material. The spacer material may comprise of a dielectric material such as silicon nitride or silicon dioxide. In the preferred embodiment, the spacer 250 comprises silicon nitride.
After spacer formation, source and drain regions 252 are doped by ion implantation, PIII, gas or solid source diffusion, or any other techniques known and used in the art. Any implant damage or amorphization can be annealed through subsequent exposure to elevated temperatures. The resistance of the source, drain, and gate can also be reduced by strapping the source, drain, and gate with a conductive material (not shown). The conductive material may be a metallic silicide such as titanium silicide, cobalt silicide, or nickel silicide. In the preferred embodiment, the conductive material is nickel suicide which may be formed by a self-aligned silicide (salicide) process.
While several embodiments of the invention, together with modifications thereof, have been described in detail herein and illustrated in the accompanying drawings, it will be evident that various modifications are possible without departing from the scope of the present invention. The examples given are intended to be illustrative rather than exclusive.
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